Exemplary apparatus can be provided which can include a laser arrangement that is configured to provide a laser radiation, and including an optical cavity. The optical cavity can include a dispersive optical waveguide first arrangement having first and second sides, and which is configured to (i) receive at least one first electro-magnetic radiation at the first side so as to provide at least one second electro-magnetic radiation, and (ii) to receive at least one third electro-magnetic radiation at the second side so as to provide at least one fourth electro-magnetic radiation. The first and second sides are different from one another, and the second and third radiations are related to one another. The optical cavity can also include an active optical modulator second arrangement which can be configured to receive and modulate the fourth radiation so as to provide the first electro-magnetic radiation to the first arrangement. The laser radiation can be associated with at least one of the first, second, third or fourth radiations.
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23. A method for optical coherence tomography imaging, comprising:
receiving, in parallel from each of a plurality of balanced receivers, a plurality of signals including a signal based on:
a first component of a first interference fringe received by a balanced receiver of the plurality of balanced receivers from a first optical demultiplexer, and
a second component of a second interference fringe received by the balanced receiver from a second optical demultiplexer,
wherein the first interference fringe and the second interference fringe are based on light reflected from a reference mirror that is received via a reference arm and light reflected from a sample that is received via a sample arm;
separating each of the plurality of signals into a plurality of I components and a plurality of q components; and
generating an A-line indicative of a structure of the sample based on the plurality of I components and the plurality of q components.
1. An apparatus, comprising:
a frequency comb optical source;
a reference arm configured to provide a first portion of light output by the frequency comb optical source to a reference mirror, and output light reflected from the reference mirror;
a sample arm configured to provide a second portion of light output by the frequency comb optical source to a sample, and output light reflected from the sample;
a coupler optically coupled to the reference arm and the sample arm, the coupler configured to output a plurality of interference fringes based on the light reflected from the reference mirror and the light reflected from the sample;
a first optical demultiplexer configured to:
receive a first interference fringe of the plurality of interference fringes; and
output a plurality of components of the first interference fringe;
a second optical demultiplexer configured to:
receive a second interference fringe of the plurality of interference fringes; and
output a plurality of components of the second interference fringe;
a balanced receiver configured to output a signal based on a first component of the first interference fringe and a first component of the second interference fringe; and
a computing arrangement configured to generate an A-line based on the output of the balanced receiver.
2. The apparatus of
wherein the reference arm is optically coupled to the second coupler and is configured to receive the first portion of portion of light output by the frequency comb optical source from the second coupler, and
wherein the sample arm is optically coupled to the second coupler and is configured to receive the second portion of portion of light output by the frequency comb optical source from the second coupler.
4. The apparatus of
a first port optically coupled to the frequency comb optical source and configured to receive light from the frequency comb optical source;
a second port configured to output at least a first portion of the light received from the frequency comb optical source; and
a third port configured to output at least a second portion of the light received from the frequency comb optical source.
5. The apparatus of
the reference mirror; and
a frequency shifter configured to:
receive light reflected by the reference mirror; and
output frequency-shifted light, wherein the light reflected from the reference mirror comprises the frequency-shifted light.
6. The apparatus of
a fourth port optically coupled to an output port of the second coupler and configured to receive the first portion of light;
a fifth port optically coupled to the reference mirror, the fifth port configured to:
output at least a portion of the light received at the fourth port; and
receive light reflected from the reference mirror; and
a sixth port configured to output at least a portion of the light received at the fifth port.
9. The apparatus of
a seventh port optically coupled to an output port of the second coupler and configured to receive the second portion of light;
an eighth port configured to:
output at least a portion of the light received at the seventh port; and
receive light reflected from the sample; and
a ninth port configured to output light reflected from the sample received at the eighth port.
11. The apparatus of
12. The apparatus of
13. The apparatus of
a tenth port optically coupled to the reference arm and configured to receive at least a portion of the light reflected from the reference mirror;
an eleventh port optically coupled to the sample arm and configured to receive at least a portion of the light reflected from the sample;
a twelfth port configured to output the first interference fringe; and
a thirteenth port configured to output the second interference fringe.
14. The apparatus of
receive the first component of the first interference fringe;
receive the first component of the second interference fringe; and
output the signal based on a difference between the first component of the first interference fringe and the first component of the second interference fringe.
15. The apparatus of
16. The apparatus of
17. The apparatus of
a fourteenth port optically coupled to the coupler and configured to receive the first interference fringe; and
a first plurality of output ports, wherein the first optical demultiplexer is configured to output from each of the first plurality of output ports a respective component of the plurality of components.
18. The apparatus of
19. The apparatus of
a fifteenth port optically coupled to the coupler and configured to receive the second interference fringe; and
a second plurality of output ports, wherein the second optical demultiplexer is configured to output from each of the second plurality of output ports a respective component of the plurality of components.
20. The apparatus of
21. The apparatus of
receive a plurality of signals output by a plurality of balanced receivers, including the signal output by the balanced receiver;
separate each of the plurality of signals into an I component and a q component;
estimate a depth-resolved scattering signal indicative of a structure of the sample based on the plurality of I components and the plurality of q components.
22. The apparatus of
an analog to digital converter configured to digitize the signal output by the balanced receiver;
a demodulator configured to separate the digitized signal into the I component and the q component; and
a Fourier transform engine configured to perform a discrete Fourier transform based on a plurality of complex signals each based on one of the I component and q component derived from one of the plurality of signals output by the plurality of balanced receivers.
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The present application is a continuation of U.S. patent application Ser. No. 16/077,294 filed Aug. 10, 2018, which is a U.S. National Stage of PCT Application No. PCT/US2017/017664 filed on Feb. 13, 2017 which relates to and claims priority from U.S. Patent Application Ser. No. 62/294,822 filed Feb. 12, 2016 and U.S. Patent Application Ser. No. 62/310,365 filed Mar. 18, 2016. Each of the preceding patent applications is hereby incorporated herein by reference in its entirety.
The present disclosure relates to optical imaging systems, and more specifically apparatus and method related to high-speed imaging of the three-dimensional scattering properties of a sample located within a large imaging volume, and especially to rapid depth-resolved imaging of a sample that has a geometric structure that causes the distance of each region of sample relative to the imaging system to vary across the sample and over time.
Optical coherence tomography (OCT) provides cross-sectional images of biological samples with resolution on the scale of several to tens of microns. Conventional OCT, referred to as time-domain OCT (“TD-OCT”), can use low-coherence interferometry techniques to achieve depth ranging. In contrast, Fourier-Domain OCT (“FD-OCT”) techniques can use spectral-radar techniques to achieve depth ranging. FD-OCT techniques have been shown to facilitate higher imaging speeds through improved signal-to-noise performance and elimination of a mechanically scanned interferometer reference arm.
FD-OCT systems generally operate by separating a light source into a sample beam and a reference beam. The sample beam can be directed at a sample to be imaged, and the reflected light from the sample is recombined with light from the reference beam (i.e., returning from the reference arm), resulting in an interference signal, which can provide information about the structure, composition and state, for example, of the sample. Light in the sample path and or light in the reference path can be modified by, for example, a phase modulator or frequency shifter, altering the characteristics of the interference and enhancing the information content of the signal or making the signal easier to detect. FD-OCT systems can sample the interference signal as a function of wavelength.
In one exemplary embodiment of the FD-OCT system, the interference signal as a function of wavelength can be obtained by using a light source that has an output wavelength which sweeps, varies or steps as a function of time. A detection of the interference signal as a function of time thereby can yield the interference signal as a function of wavelength. This exemplary embodiment can be referred to as optical frequency domain imaging (“OFDI”) technique.
In another exemplary embodiment of the FD-OCT system, the interference signal as a function of wavelength can be obtained by using a broadband light source and a spectrally dispersing unit or a spectrometer that spatially separates the recombined sample and reference light according to wavelength such that a one-dimensional or two-dimensional camera can sample the signal as a function of the wavelength. This exemplary embodiment can be referred to as spectral-domain OCT technique. In both such exemplary embodiments, the detected interference signal as a function of wavenumber k (k=1/wavelength) can be used to provide information related to the depth profile of scattering in a turbid or semi-turbid sample, or a transparent sample. Such information can include information regarding, e.g., the structure of the sample, composition, state, flow, and birefringence.
A scatterer at a given depth can induce a modulation in the amplitude or polarization of the interfered signal. The frequency of such modulation in wavenumber-space can be related to the location of the scatter or the time delay of the light reflected from that scatter relative to the time delay of the light in the reference arm. Scatterers located at a depth that causes reflected signals with no net time delay relative to the reference arm light can induce an interference signal that may not modulate with wavenumber. As the location of the scatterers moves from this zero-delay point, the magnitude of the frequency can increase. To image over large delay windows, e.g., to detect and localize reflections within large time delay window, the interference signal may often be sampled with sufficiently high resolution in wavenumber-space to facilitate an unambiguous detection of the range of modulation frequencies that are associated with the large delay window.
To accommodate the sampling at high resolution in wavenumber, increasingly fast analog-to-digital converters (“ADC”) can be used in the OFDI systems, and increasingly high pixel count cameras can be used in the SD-OCT systems. In both the OFDI and SD-OCT systems, the increased data volume resulting from imaging over large extents can often result in the use of increasingly-high bandwidth data transfer buses and data storage units.
Optical-domain subsampling can be used to increase the depth range of an OFDI or SD-OCT system without increasing the number of spectral measurements that are performed. In addition, optical-domain subsampling can be used to increase the imaging speed without increasing the electrical bandwidth of the imaging system. In this manner, an optical-domain subsampling OCT system can interrogate a larger volume of physical space with a given number of measurements than a FD-OCT or a SD-OCT system that is operated with the same number of measurements.
In a high-speed optical domain subsampled OCT system, it is possible to image across large depth ranges at extremely high speeds resulting in video-rate volumetric microscopy of samples that are not precisely located relative to the imaging system or contain a surface that varies in distance to the imaging system across the field.
Accordingly, there is a need to address and/or overcome at least some of the deficiencies described herein above.
In particular, at least some of the deficiencies with the conventional systems and method can be addressed with an exemplary apparatus which can include a laser arrangement that is configured to provide a laser radiation, and including an optical cavity. The optical cavity can include a dispersive optical waveguide first arrangement having first and second sides, and which is configured to (i) receive at least one first electro-magnetic radiation at the first side so as to provide at least one second electro-magnetic radiation, and (ii) to receive at least one third electro-magnetic radiation at the second side so as to provide at least one fourth electro-magnetic radiation. The first and second sides are different from one another, and the second and third radiations are related to one another. The optical cavity can also include an active optical modulator second arrangement which can be configured to receive and modulate the fourth radiation so as to provide the first electro-magnetic radiation to the first arrangement. The laser radiation can be associated with at least one of the first, second, third or fourth radiations.
In one exemplary embodiment, the first arrangement can be a fiber Bragg grating (FBG), a chirped FBG, and/or a FBG array. The FBG can be provided in a polarization maintaining optical fiber and/or a non-polarization maintaining optical fiber. The first arrangement can also be configured to cause a group delay that varies linearly with an optical frequency of the first radiation and/or the third radiation. According to another exemplary embodiment, the first arrangement can include (i) at least one first circulator which receives the first radiation and transmits the second radiation, and/or (ii) at least one second circulator which receives the third radiation and transmits the fourth radiation. The optical cavity can include at least one optical amplifier third arrangement which can be configured to amplify at least one of the first radiation, the second radiation, the third radiation or the fourth radiation. The optical amplifier arrangement can include a semiconductor amplifier, a Raman amplifier, a parametric optical amplifier, and/or a fiber amplifier. The optical cavity can also include a further active optical modulator fourth arrangement which can be configured to receive and modulate the second radiation so as to provide the third electro-magnetic radiation to the first arrangement. For example, the further active optical modulator fourth arrangement can be configured to suppress a light radiation that travels through the first arrangement, which is different from the second radiation. Additionally or alternatively, the further active optical modulator fourth arrangement can be a further active optical amplifier arrangement.
According to a further exemplary embodiment of the present disclosure, the optical cavity can include at least one optical polarizer fifth arrangement, which is configured to block a light radiation transmitted through the first arrangement. The optical cavity can also include a dispersion compensating arrangement and/or a fixed periodic spectral filter arrangement. The fixed periodic spectral filter arrangement can include (i) a Fabry-Perot etalon filter that has a finesse that is between 3 and 25, and/or (ii) an optical interleaver. The Fabry-Perot etalon filter can be an air gap etalon filter.
In a still further exemplary embodiment of the present disclosure, the laser radiation can have a wavelength that changes over time, e.g., continuously and/or discretely. For example, actions by the first and second arrangements can cause the wavelength to change at a rate that is faster than 80 nm/micro seconds.
In further alternative embodiments, the first arrangement can include a fiber Bragg grating (FBG) that is provided in a polarization maintaining optical waveguide, the first radiation can be launched along a first birefringent axis of the optical waveguide, and the third radiation can be launched along a second birefringent axis of the optical waveguide, with the first and second birefringent axes being different from one another. The second electro-magnetic radiation can be a reflection of the first electro-magnetic radiation, and the fourth electro-magnetic radiation can be a reflection of the third electro-magnetic radiation.
According to yet another exemplary embodiment of the present disclosure, an exemplary apparatus can be provided which can include a laser arrangement that is configured to provide a laser radiation, and including an optical cavity. The optical cavity can include a dispersive first arrangement can be configured to receive at least one first electro-magnetic radiation so as to provide at least one second electro-magnetic radiation, and a dispersive second arrangement which is configured to receive at least one third electro-magnetic radiation so as to provide at least one fourth electro-magnetic radiation, whereas the second and third radiations are related to one another. The optical cavity can further include an active optical modulator second arrangement which can be configured to receive and modulate the fourth radiation so as to provide the electro-magnetic radiation to the first arrangement, with the laser radiation being associated with at least one of the first, second, third or fourth radiations. The laser arrangement can also include an interferometer arrangement which is configured to generate (i) a fifth electro-magnetic radiation from the laser radiation in a sample arm, (ii) a sixth electro-magnetic radiation from the laser radiation in a reference arm, and (iii) an interference signal based on an interference between the fifth electro-magnetic radiation and the sixth electro-magnetic radiation. The laser arrangement can also include a beam scanning arrangement configured to scan the fifth electro-magnetic radiation across at least one portion of at least one sample. An interaction between the laser arrangement, the interferometer arrangement, and the beam scanning arrangement provides a three-dimensional measurement of an optical property of the portion(s) of the sample(s).
For example, according to one exemplary embodiment, the laser arrangement can further include an analog-to-digital acquisition arrangement configured to obtain the interference signal based on an electronic clock signal, and an electronic signal generator configured to drive the second arrangement, whereas the electronic clock signal can be phase-locked to the electronic signal generator. The first and second arrangements can include fiber Bragg gratings or part of the same fiber Bragg grating. The second electro-magnetic radiation can be a reflection of the first electro-magnetic radiation, and the fourth electro-magnetic radiation can be a reflection of the third electro-magnetic radiation. The laser radiation can be an optical frequency comb.
According to yet another exemplary embodiment of the present disclosure, an exemplary apparatus can be provided which can include a laser arrangement that is configured to generate a laser radiation at a particular number (N) of discrete optical frequencies. The exemplary apparatus cam also include an interferometer arrangement configured to generate an interference signal from the laser radiation, and a beam scanning arrangement configured to scan at least one portion of the laser radiation across at least one portion of at least one sample. A line width of each of the discrete optical frequencies can be less than 10 GHz, and a spacing between each of the discrete optical frequencies can be greater than 20 GHz. The laser radiation can step between the discrete optical frequencies at rate that is greater than 20 million discrete optical frequency steps per second. In a further exemplary embodiment of the present disclosure, the laser arrangement can include a continuous fiber Bragg grating having a length that is greater than 2 meters, and or a fiber Bragg grating array having a length that is greater than 2 meters.
According to a still further exemplary embodiment of the present disclosure, method computer-accessible medium (e.g., having software stored thereof to be executed by a computer) can be provided for displaying a video stream regarding at least one structure. For example, using such method and computer-accessible medium, it is possible to measure four-dimensional interferometric data regarding different portions of at least one structure at different points in time, wherein the four-dimensional data describing at least one optical property of the at least one structure. Further, it is possible to transform the four-dimensional interferometric data into two-dimensional video data, and display the video stream of the different portions of the structure using the two-dimensional video data. A latency of a performance of the measurement and the display is less than 1 second.
The exemplary procedures performed by such exemplary method and computer are done so in a medical procedure, and further can cause the procedure to be guided interactively using the video stream. Additionally, the measurement can be performed using a frequency comb optical source. Alternatively or additionally, the measurement can be performed using a laser arrangement as described in various embodiments herein above.
According to a still further exemplary embodiment of the present disclosure, method computer-accessible medium (e.g., having software stored thereof to be executed by a computer) can be provided to be used in a medical procedure on at least one anatomical structure. Using such exemplary method and computer, it is possible to measure single-dimensional interferometric data describing at least one optical property of the structure at a rate that greater than 5 Mega Hertz. Further, it is possible to construct four-dimensional interferometric data from the single-dimensional interferometric data regarding different portions of at least one structure at different points in time, and utilize the four-dimensional interferometric data in the medical procedure. For example, the measurement can be performed using a frequency comb optical source. Alternatively or additionally, the measurement can be performed using a laser arrangement as described in various embodiments herein above.
According to a yet still further exemplary embodiment of the present disclosure, method computer-accessible medium (e.g., having software stored thereof to be executed by a computer) can be provided for displaying a video stream regarding at least one structure. For example, using such method and computer-accessible medium, it is possible to measure four-dimensional interferometric data regarding different portions of at least one structure at different points in time, whereas the four-dimensional data describing at least one optical property of the structure, and the four-dimensional interferometric data can be circularly wrapped in a particular spatial dimension. Additionally, the exemplary method and computer can transform the four-dimensional interferometric data into two-dimensional video data by compressing the particular spatial dimension, and display the video stream of the different portions of the structure using the two-dimensional video data.
For example, the compression can include (i) locating a position of a surface of the structure within the four-dimensional interferometric data, and (ii) controlling the compression using the position. Further, the measurement can be is performed using a frequency comb optical source, and/or a laser arrangement as described in various embodiments herein above.
These and other objects, features and advantages of the present disclosure will become apparent upon reading the following detailed description of exemplary embodiments of the present disclosure, when taken in conjunction with the appended drawings and claims.
Further objects, features and advantages of the present disclosure will become apparent from the following detailed description taken in conjunction with the accompanying figures showing illustrative embodiments of the present disclosure, in which:
Throughout the figures, the same reference numerals and characters, unless otherwise stated, are used to denote like features, elements, components or portions of the illustrated embodiments. Moreover, while the subject disclosure will now be described in detail with reference to the figures, it is done so in connection with the illustrative embodiments. It is intended that changes and modifications can be made to the described exemplary embodiments without departing from the true scope and spirit of the subject disclosure and the appended claims.
Optical-domain subsampled OCT is referred hereafter to as optically subsampled OCT (OS-OCT). In one exemplary embodiment of the present disclosure, an imaging system can be provided that is based on optical frequency domain imaging (OFDI). Unlike conventional OCT systems that utilize wavelength-swept sources wherein the source wavelength varies substantially continuously with time, OS-OCT can use a wavelength-stepped source, where the source has a wavelength that varies in a stepwise fashion with discrete jumps in wavelength separating periods wherein the wavelength is substantially constant.
The power trace can be flat as a function of wavelength, and/or can vary according to, for example, the spectral response of the gain medium used in the source, or can be made to follow a particular profile. During the times 135a-135f between wavelengths, the power of the exemplary laser source can be modulated and/or turned off. While the wavenumber output shown in
In another exemplary embodiment of an exemplary optically subsampled (OS-OCT) imaging system shown in
Si∝√{square root over (P(ki))}e(√{square root over (−1)})θ(k
where P(ki) is the reflected signal power corresponding to wavenumber ki and θ(ki) is the phase difference between the reference arm light and reflected sample light corresponding to wavenumber ki. The complex signal S (including, e.g., a combination of 270 and 280) can be forwarded to a data processing and recording unit 260 (which can include one or more computers or one or more processors).
In an exemplary embodiment of the present disclosure, the complex demodulator 240 can be based on polarization-based demodulation apparatus, e.g., as described in Vakoc, Optics Letters 31(3) 362-364 (2006) U.S. Patent Publication No. 2007/0035743. In another exemplary embodiment of the present disclosure, a phase modulator can be placed in either the reference arm 210 or the sample arm 220. The exemplary phase modulator can be provided, configured and/or structured to induce, e.g., a phase shift of π/2 radians or 0 radians, such that two measurements can be made at each of these phase shifts for each wavenumber channel, providing time-multiplexed in-phase and quadrature signals necessary to construct the complex signal S. In another exemplary embodiment of the present disclosure, the complex demodulator can be based on the use of a 3×3 couple, as described in, e.g., Choma, Optics Letters 28(22) 2162-2164.
In the exemplary embodiment described above, the data processing and data storage unit 260 (see
The use of subsampled optical imaging to increase the effective depth range is illustrated in
Using conventional OCT or OFDI techniques, the imaging system 500 can acquire data over the full depth range (d2−d1+δ), where the parameter δ 522 describes the imaging depth into the sample. A conventional OCT or OFDI image 550 provides the image as a function of depth 521 and angle 523. The exemplary image occupies a depth range given by d2−d1+δ. Acquiring data over this large area in a short time requires fast digitization and data transmission capabilities. Such exemplary image can also indicate that the acquisition may be inefficient. This can be because, in that large areas of the acquired image, there is little or no information content either above the tissue surface 533a or a depth greater than δ below the tissue surface 533b. The use of subsampled optical frequency domain imaging or subsampled SD-OCT can facilitate an acquisition of the same information content, and with a greater efficiency. An exemplary subsampled OFDI image 560 is provided as a function of depth 561 and angle 564. The exemplary imaging system 500 can be configured to provide an imaging range of δ 562. This exemplary imaging range does not have to be greater than the imaging penetration depth into the sample, and can alternatively be less if information is desired over a more shallow region. The wrapping properties of an exemplary subsampled imaging procedures can facilitate a capture of information from the superficial depth δ of the sample at all angles. Furthermore, an exemplary imaging acquisition bandwidth is likely not dedicated to the empty space above the tissue surface, or below the imaging penetration into the tissue.
It is possible to locate or otherwise determine the tissue surface 570 using surface finding procedures, including, for example, snake procedures (as described in Yezzi, et. al., IEEE Tran Med Imag 16,2 199-209 (1997)), and to unwrap the exemplary image to generate an image 590 where the tissue is shown with a surface that is approximately constant in depth.
Exemplary embodiments of a high-speed optically subsampled imaging system and image display apparatus and methods according to the present disclosure are described herein below, and illustrated in
For example,
The light or other electro-magnetic radiation from the dispersion compensating fiber can be amplified by, e.g., a broadband semiconductor optical amplifier (614, 611) that can include optical isolators to prevent light/radiation passage in the counter-clockwise direction. This amplified light is passed through a set of two identical FP etalons with 200 GHz FSR 613. The laser can be operated with one etalon, or a plurality of etalons. The exemplary etalon(s) can transmit light or other electro-magnetic radiation at approximately equally spaced wavenumbers. For example, two FP etalons can be used in one exemplary embodiment to narrow the optical transmission spectrum of the combined filter and to improve noise performance and reduce nonlinear interactions in the amplifiers and fibers. An output coupler 616 can be placed after the filters 613, and directed approximately 20% of the light out of the cavity. The exemplary coupling ratio of the output coupler 616 can be set over a large range. In such exemplary embodiment of the present disclosure, the length of each dispersive element can be selected to substantially match in magnitude, and also have opposite signs across the operating bandwidth.
The intensity modulator 610 can be driven by a pulse generator 622 producing a pulse of a tunable length and a tunable repetition rate. In one exemplary embodiment, the pulse length can be between 0.05 ns and 5 ns, although other ranges of the pulse length are possible. Such exemplary pulse length can provide a temporal window with high optical transmission through the modulator 610. The intensity modulator 610 can also provide a high on-off extension ratio (approximately 30 dB) through optimization of the lithium niobite waveguide properties can be used to limit the transmitted light when in the “off” state. Alternatively or in addition, an electro-optic intensity modulator can be used, or a semiconductor gain element can be current modulated to provide this intensity modulation function. A polarizer can be included prior to the modulator 610 to compensate for a modulator that has polarization-dependent operation, and a polarization controller can be placed between the polarizer and the modulator to align the returned light polarization state to the optimal axis of the modulator. For example, polarization controllers can be included throughout the laser cavity to align light polarization states at each element.
In one exemplary embodiment of the present disclosure, the pulse generator 622 can be driven at, e.g., about 18.9 MHz, which can be the 4336th harmonic of the fundamental cavity frequency given by the inverse of the cavity round trip time. By operating at this exemplary harmonic, the pulses that return to the intensity modulator can be matched to a transmission window and pass through the exemplary modulator. At the modulator, most or all lasing wavelength pulses can be temporary overlapped within a single multi-wavelength pulse. After passing through the dispersive fiber, these pulses can be temporally separated. The second dispersive fiber can then recompress these pulses. Each pulse at the modulator can be stretched to produce a pulse train with each pulse in the pulse train having a separate wavelength. Multiple pulse trains are present in the cavity at any given time.
The laser output can provided from the output coupler 616. This output can be passed through a further optical amplifier to increase power, and/or it can be further filtered by one or several wavelength selective filter, such as, e.g., FP etalons 619 to improve line width and/or reduce ASE light transmission. The output pulse train can be stretched or compressed in time using a dispersion compensating element (or a positive dispersion element) 618 that can be or include, for example, a dispersion compensating fiber or a fiber Bragg grating array operated in reflection mode, or a chirped fiber Bragg grating operated in reflection mode. The external dispersion element 618 can be used to modify the A-line duration and the associated required digitization speed externally without modifying the laser cavity.
Additional amplifiers 617, 620 can be included to increase power and improve line width. These amplifiers can be based on semiconductor optical amplifiers but can constructed for example by doped optical fibers or utilize Raman gain. The use of the filters external to the laser cavity 619 can remove background amplified spontaneous emission light and narrow the line width of each wavelength pulse. The amplification and filtering can be repeated in multiple stages to further increase power and optimize line width.
In one exemplary embodiment of the present disclosure, the laser output can include a pulse train 640 with each pulse having a distinct wavelength corresponding to the transmission pass band of the filters 613, 619. This can be visualized by a high-speed opto-electronic receiver and captured on a high-speed oscilloscope. The length of such exemplary pulse train 641 in the exemplary embodiment according to the present disclosure can be set to approximately 50 ns, although other settings are conceivable within the scope of the present disclosure. Each pulse train denotes an “A-line” in OCT imaging, and can contain distinct pulses each of which can have a unique wavelength that is approximately equally spaced in wavenumber and matches the wavelength selective filter transmission peaks. The optical spectrum of the output laser 630 can be a comb structure with substantially distinct bands of output wavelength 631.
The exemplary spectral output 630 is illustrated in
The effective A-line rate of the laser can be changed by operating the intensity modulator at different harmonics of the fundamental cavity round trip frequency (or equivalently at different pulse repetition times that are subharmonics of the cavity round trip time). This can facilitate the A-line repetition rate to be changed electronically. The magnitude of the dispersion can be adjusted to modify the A-line length by adjusting the temporal spacing between each wavelength pulse. While these elements are shown in a particular organization and/or order in
In an exemplary embodiment of the present disclosure, an output of the high-speed laser source 700 can be directed to the input of an interferometer 701 (as shown in a block diagram of
Alternatively or in addition, such exemplary optical circuit can be constructed in free-space using bulk optic splitters and polarization rotators. The outputs of each polarization beam splitters can be passed to opposite signed inputs of balanced receiver 808a, 808b, 808c, 808d for an intensity noise reduction. The signal can be low-pass filtered using filters 809a, 809b, 809c, 809d. The cut-off frequency of these low-pass filters can be set to match the frequency bandwidth of baseband window resulting for optical subsampling of the laser which can be approximated as 1/(2*dT) where dT is the temporal spacing of the wavelength pulses from the laser, and/or can be approximated as the minimum temporal spacing of the wavelength pulses from the laser if the temporal spacing is not equal across the A-line. For example, 50/50 optical couplers 805a, 805b can be included in the exemplary system.
When the MI and MQ signals are added in quadrature, there can be a reduction in the complex conjugate artifact resulting from conjugate ambiguity in one signal measurement. The amount of reduction, e.g., is the conjugate artifacts correlates with how closely the relationship between MI and MQ are to being in perfect quadrature (e.g., about 90 degree phase separation). In order to reduce the number of RF channels, demodulators can be provided that create the information needed to generate MI and MQ through sequential phase modulation in the reference or sample arm of the interferometer using for example a lithium niobate phase modulator or an acousto-optic modulator.
Imperfections in the quadrature relationship between the detected interference fringes MI (e.g., detected on signal 809a) and MQ (e.g., detected on signal 809b) can result in an imperfect separation of signals from positive and negative delay spaces. In this exemplary embodiment, the measured signals can be modified after acquisition by a digitizer 810a, 810b and transfer of the digitized signals to a computing arrangement (e.g., a computer, a processor and/or a multiple or combination thereof). These exemplary modifications can be used to correct for these errors using known techniques, as described, e.g., in Siddiqui, et. al., Optics Express 23,5 5508-5520 (2015). Such exemplary corrections can be performed using pre-determined data acquired from a separate sample such as a set of mirror (see the mirror 713 in
An exemplary demodulation circuit can operate on subsampled measurements similar to conventional Fourier-Domain measurements, as described in Siddiqui, et. al., Optics Express 23,5 5508-5520 (2015). In one example shown in
An exemplary procedure used for processing acquired signals from a mirror structure to derive the post-processing correction factors is described below and shown in
An exemplary embodiment of the high-speed optically subsampled OCT system can utilize phase-synchronized clocking systems across many system modules as illustrated in
The clock frequency for the exemplary digitizers 1112, 1113 can be configured to be an integer multiple of the laser A-line rate that resulted an integer number of digitized samples for each A-line. This can facilitate multiple A-lines to be averaged directly, i.e., in the measured fringe domain or after FFT as a complex A-line, without needing to account for A-line phase shifts. For example, in this exemplary system, the pattern/pulse generator 1105 can be driven by, e.g., a 3.64437734 GHz signal by the signal generator 1108; the pattern generator 1105 was set by the computer 1109 to produce 192 bits at this frequency and remain “on” for one bit out of this 192 bit sequence, yielding an Aline rate of 3.64437734 GHz/192=18.9811319791667 MHz. The digitizer clock was set to, e.g., 1.23377357865 GHz by an external clock 1111 to provide, e.g., exactly 65 measurements per A-line. For example, a set of continuous acquisitions can be combined to generate a coherently averaged A-line with an improved SNR and an addition of fringe signals. This exemplary coherent averaging of A-lines can be performed using a processor that is on the digitizer board such as a field programmable gate array (FPGA) or using the computer arrangement.
A further exemplary imaging microscope can also be provided by using, e.g., a 3.9 kHz resonant beam scanner along with a slower galvanometric scanner. It is possible to utilize a 250 mm focusing lens. With the exemplary 3.9 kHz resonant fast-scanner, it is possible to obtain approximately 8 volumes per second while measuring ˜2428 pixels in the fast frame and 1000 pixels in the slow frame. This procedure and arrangement facilitated volumetric imaging of samples with each volume acquired at video rate, e.g., at 8 volumes per second. The exemplary volume acquisition rate can be increased significantly by reducing the number of A-lines in the fast frame direction, the slow frame direction, and by increasing the speed of the scanner. This imaging was performed with the 18.9 MHz A-line rate source. Because of the sinusoidal nature of the resonant scanner, as shown in
In another exemplary embodiment of the system according to the present disclosure, the polarization-diverse volumetric tissue imaging was used to measure the optical birefringence and optical axis of that birefringence within a tissue field, and these volumetric measurements were acquired with the video-rate microscope, allowing video-rate birefringence imaging of a surgical field. In such exemplary embodiment, the four digitizer channels (e.g., digitizer channels 810a, 810b of
In this example, the fast scanner was operating at 3.945 kHz, and a modulation was performed between input polarization 1 during the forward scan and input polarization 2 during the backward scan (e.g., EOM modulation speed was 3.945 kHz). The slow axis scanner had a speed of 6.514083 Hz, and was driven with a ramp waveform therefore providing 600 transverse forward (fast-axis) scans and 600 backward (fast-axis) scans in a volume. A transverse field of 1.2 cm×1 cm was measured. The depth range of the exemplary subsampled OCT system was approximately 5 centimeters. Such exemplary data was acquired with a 200 GHz output wavenumber spacing yielding a baseband imaging window depth of approximately 500 μm in tissue.
In an exemplary embodiment, the polarimetric data can be displayed by mapping the three optical axis parameters of a Stokes representation of polarization to red, green and blue color scales, and then median projecting these color volumetric images across depth to generate a two-dimensional map of tissue optical birefringence 1503, 1504, 1505,1506, 1507.
Alternatively, as shown in
The exemplary laser source shown in
Alternatively or in addition, a repetitive dispersive element can be used to temporally disperse each of the wavelength pulses without affecting the temporal separation of the pulses. For example, a Gires-Tournois etalon with a FSR matched to that of the wavelength-selective filter or at an integer multiple of the wavelength-selective filter of the laser can be utilized at the laser output to create a large dispersion within the limited bandwidth of each pulse leading to pulse stretching. The exemplary group delay response of this filter can be periodic 1715 such that each pulse is temporally broadened (or compressed if configured in such exemplary manner) without inducing a significant modification of the pulse-to-pulse spacing. The exemplary laser as shown in
In another exemplary embodiment of the present disclosure, the wavelength selective filter can be constructed from an air-cavity Fabry-Perot etalon which has the advantage of not using a dispersive media in the etalon and maintaining a constant free spectral range across a large bandwidth. Alternative wavelength filter configuration can include fiber-based Fabry-Perot etalons, virtually imaged phase array gratings, fiber-Bragg gratings or other waveguide Bragg gratings, arrayed waveguide gratings, cyclic arrayed waveguide gratings, or optical interleavers and deinterleavers, among others.
According to yet another exemplary embodiment, the dispersive elements within the laser cavity (shown in
The exemplary reflection bandwidth of the FBGs can be broad such that the laser line width is determined by the etalon line width. A variable optical attenuator 1805 can be included in the array to, e.g., limit the number of reflected pulses to reduce the number of lasing wavelengths. The input light from one side 1801a can be reflected and thereby creates an output light 1801b with each wavelength providing a different group delay based on the location of the FBG that aligns to its wavelength, or to the first FBG encountered by the light that matches to its wavelength. The exemplary FBG array configuration can also be used from both sides, with light launched form the other end 1802c reflecting off the same gratings and returning 1802d and can have the opposite dispersion as that achieved in the reflected light 1801b due to the input light 1802a seeing the FBGs in the reverse order. Alternatively or in addition, a second FBG array can be used to create an opposite dispersion with the order of the gratings in this array reversed. The FBG reflectivity 1804 versus wavelength 1803 can be tailored by the grating writing process to configure its line width, reflectivity, phase response, and center wavelength as shown in the graph of
In a further exemplary embodiment, a chirped FBG can be used that provides continuous wavelength reflectivity along the fiber length. For example, a wavelength selective filter in the cavity can define the lasing wavelength and the chirped FBG can create the positive and negative dispersion(s). As with the exemplary FBG array, the same chirped FBG can be used to create positive and negative dispersion(s) by launching from opposite sides. The reflectivity of the chirped FBG can be designed to induce a specific laser output profile and/or to compensate for wavelength-dependent loss or gain in the cavity. The exemplary laser can be configured without a wavelength selective filter in the cavity to, for example, generate a continuous wavelength-swept output providing a laser source for high-speed conventional FD-OCT.
The spacing of the exemplary FBGs in a FBG array can be, for example, about 5 cm (Δx=5 cm) in fiber, thereby producing a 0.5 ns temporal displacement between reflections of light at wavelengths corresponding to adjacent FBGs. For example, FBGs can be placed closer to shorten this time separation, and further to lengthen it. FBG arrays of tens of centimeters through hundreds of meters can be provided.
To reduce or otherwise minimize the transmission of light through a FBG array or a continuously chirped FBG dispersive element, the reflectivity of the grating can be made close to 100%, limiting significantly the transmission. This can be done, for example, to prevent a lasing path within the laser cavity that by-passes the intensity modulator.
In an alternative exemplary embodiment of the present disclosure of a exemplary configuration 1901 shown in
In the exemplary embodiment of the laser system shown in
In a further exemplary embodiment, an FBG array or continuously chirped FBG can be provided from a polarization-maintaining fiber to ensure that reflected light or other electro-magnetic radiation from all wavelengths is in approximately the same polarization state. The exemplary FBG array or continuously chirped FBG can additionally be provided in reduced cladding mode fiber to remove side-modes in the FBG reflectivity.
In another exemplary configuration, an FBG array or continuously chirped FBG can be based on polarization-maintaining (PM) fiber and the light or other electro-magnetic radiation entering from one side can be launched along a fast axis, and the light launched from the other side can be launched along the slow axis. In this exemplary configuration that uses a FBG array, the shift in the reflectivity of each grating in the fast and slow axis can be configured to match the wavelength spacing of the laser. Using such exemplary embodiment, it is possible to prevent lasing due to light transmission through the grating by for example placing polarizers one or both sides of the grating 2011. For example, polarizers 2012a, 2012b can be used with polarization controllers 2013a, 2013b. Light or other electro-magnetic radiation launched in the fast axis from the left through polarizer 2012a and that is transmitted through the grating 2014 can be blocked by the polarizer 2012b. The reflectivity of the FBGs can be configured to induce a specific laser output profile or to compensate for wavelength-dependent loss or gain in the cavity.
In a still further exemplary embodiment, the WSF element can be omitted from the cavity and the FBG array can define the lasing wavelengths and the line width of each lasing wavelength depends on the bandwidth of the reflectivity of each FBG. Alternatively or additionally, a continuously chirped FBG array can be used as dispersive elements without additional wavelength selective elements and creating a continuously swept wavelength source.
In another exemplary embodiment, an FBG array can be used and configured to limit the transmission through the array which can be used to prevent light circulation in an unintended path. For example,
In an alternative exemplary embodiment, the FBG array used to create dispersion can include two or more gratings at each wavelength 2101 and position 2103 as shown in panel 2190 of
The light/radiation that passes through the first and second frequency shifters 2306, 2307 therefore likely have no net frequency shift. However, light/radiation that circulates without seeing the intensity modulator are continuously upshifted by +F per round trip. +F can be for example 1 GHz and the line width of the wavelength selective filters 2304a,b can be for example 1 GHz. This can cause the light/radiation to walk-off from the pass band of the wavelength selective filters and suppress light circulation in this path. In the exemplary case of an FBG array, the line width of the bi-directional dispersion element 2303 can be configured to be sufficiently wide-band to reflect light that is upshifted once +F by the frequency shifter 2306. The frequency shifters 2306, 2307 can be constructed, for example, using acousto-optic frequency shifters or electro-optic modulators, and can additionally be or include phase modulators. In another exemplary embodiment configured to use phase modulators, the second phase modulator 2307 can induce a phase modulation that is opposite to that induced by the first phase modulator 2306. In this exemplary manner, the first phase modulator can spectrally broaden the light, while the second phase modulator compensates for this broadening and allows the light to pass through the wavelength selective filter pass band. The laser output 2308 is provided by the output coupler 2309.
In a similar exemplary embodiment illustrated in
In another exemplary embodiment, the exemplary system can be provided to limit light/radiation circulation in an unintended path, and thus the component 3509 can be a polarizer. The light/radiation traveling in this path can be set to X polarization state by polarization controller 3510b and the polarizer 3509 can be set to pass this polarization state. Light/radiation reflecting from the bi-directional dispersion element 3503 can be configured using polarization controllers to return in the X polarization state, and pass through the polarizer 3509. In particular, the light/radiation that is transmitting through the bi-directional dispersion element 3503 can be configured using polarization controllers to have an orthogonal Y polarization state (as set by a polarization controller 3510d) and can be attenuated by the polarizer 3509. This polarizer 3509 can be placed anywhere in the path connecting components 3502a, 3505, 3502b, and 3503. For example, the optical amplifier 3505 can serve as a polarizer because of its polarization-dependent gain.
In a further exemplary embodiment, additional dispersion is generated using optical interleaver/de-interleavers. In particular,
In this exemplary embodiment, the dispersion used by the element 2404 can be reduced to that sufficient to separate even wavelengths or odd wavelengths on their own, and the interleaves 2405a, 2405b can be used to displace the even/odd wavelength sets. The input power at the interlayer 2405a,b can be for example shown in 2410, and the output power on ports a is shown on 2411, while the output power on ports b is shown on 2412. The optical interleaved channel spacing can be designed to match that spacing of the laser that is set by the wavelength selective filter 2417a, 1417b. According to such exemplary configuration, the laser output does not proceed monotonically in wavelength and instead proceeds first through the odd wavelengths and then proceeds through the even wavelengths, for example, in the order: [λ1, λ3, λ5, λ7, λ9, λ2, λ4, λ6, λ8, λ10] for a ten-wavelength laser. An exemplary OS-OCT imaging system using such exemplary digitizer and computer arrangement 2501 can acquire these signals temporally 2502, and reorganize the measurements in memory 2503 prior to processing by, for example, Fourier transformation 2404, as illustrated in
In a further exemplary embodiment, the source dispersion properties can be configured to generate an output pulse train that is substantially uniformly spaced in time by for example controlling the dispersion profile in the intracavity dispersion elements.
In a further exemplary embodiment, the exemplary laser source can be configured to include the source polarization modulating between two state of polarizations (SOPs). For example, the output of the wavelength stepped laser can be split into two paths and the polarization is rotated in one path and the two beam are recombined to create a dual polarization-state source.
The exemplary system shown in
In this exemplary configuration, light/radiation from path B can be suppressed. The time T2 can for example be equal to T1, or can be smaller than T1. In can be understood that the modulation pattern in 3260 can for example be a smoothed modulation such as a sinusoidal modulation. The dispersive element 3233 can be configured to produce wavelengths at the gain peak during the times when cavity path A has the lowest overall gain such as at the edges of the time windows 3262a, 3262b, and produces wavelengths at the edges of the gain peak during times when the gain is highest, such as in the central region of the time windows 3262a, 3262b. The modulation of loss and gain can be performed for example by modulating the current 3240 used in a semiconductor optical amplifier 3234, and/or by insertion of an additional modulator or gain element 3250 controlled by signal 3251. For example, the control signals 3240 and 3251 can be for example synchronized with the drive signal 3241. The duty cycle of the output light 3238 can be increased by splitting the light into two paths and delaying one path relative to the other by approximately the length of one A-line and recombining. In this second path, the light/radiation can, for example, polarization rotated to create adjacent A-lines with different polarizations, as shown in
The phase shifting that can be performed by the modulator 2950 can be configured to phase shift adjacent optical pulses from the exemplary source, as shown in a graph 3000 of
The detected signal 3311d can then be transmitted or otherwise provided to a computing arrangement 3311e shown in detail as a computer arrangement 3340. For example, the signal 3341 can be digitized by an analog-to-digital converter 3342 provided in the computer arrangement 3340, and such signal information 3343 can be separated into the I 3345 and Q 3346 components using, for example, a demodulator 3344. Such exemplary demodulator 3344 can be or include an l/Q demodulator based on frequency mixing using known techniques when the device 3304 is, e.g., a frequency shifter, such as an acousto-optic frequency shifter. The signals 3345, 3346 can define the complex interference signal at λ1, and can be one portion of an input into a Fourier transform engine 3347 that can be used (along with information from other wavelengths) to calculate or otherwise determine the depth-resolved scattering signal 3348 using known Fourier-domain OCT processing. The additional wavelength signals cam be analyzed in a similar manner using the additional output ports of the demultiplexers 3310a, 3310b using a similar exemplary embodiment of the system and method that is described herein for λ1.
In one exemplary configuration for N points in a A-line/fringe, there can be N averaging engines. The N+1 sample can then be returned to the first averaging engine 3107. Such exemplary procedure can be repeated for i iterations, and the value after i iterations can be output 3107a from the averaging engine 3107 as a 16-bit word. The set of 16-bit words 3107a, 3108a, 3109a, etc. can define an averaged fringe, where 3108a can be generated by an averaging engine 3108 and 3109a is generated by an averaging engine 3109. Here we note that the digitizer 3102 can be operated at a higher bit-depth. This digitizer arrangement 3100 allows a lower-bit depth digitizer to be used while improving dynamic range and signal fidelity through fringe averaging. This exemplary digitizer system can be performed in part on a computer or a field programmable gate array. For example, the digitizer clock input 3180 can be synchronized to the laser such that the digitizer clock, laser A-lines, and resulting fringes remain highly synchronized. This on-board processor can also perform core signal processing such as the FFT. This can facilitate the optically subsampled system to perform real-time processing and image display. Additionally, the digitizer can be configured to continuously stream the acquired data to a computing arrangement allowing for continuous imaging or real-time continuous imaging. The signal can be digitized at a bit depth other than 8 bit such as 10 bits and can be converted to another bit depth than 16 bit such as 12 or 14 bit.
In another exemplary embodiment of the present disclosure, the digitizer can utilize a sample, and hold or an integrate and hold functionality that accumulates the signal across the pulse duration and return the accumulated measurement, as an alternative to conventional digitizers used with low-pass filters. In another exemplary embodiment, the signal roll-off that occurs as frequencies near the Nyquist edge of the subsampled baseband image can be offset by amplifying the signals as a function of depth, and selecting such amplification to match the roll-off of the OS-OCT system.
In a further exemplary embodiment of the present disclosure, the optically subsampled imaging system can be operated with a small scanned beam probe that can be used to image internal sites. This exemplary scanning probe can be based on a fiber-scanning architecture, on a small MEMs based mirror, on a rotating prism or rotating probe design. In addition, this probe can be configured to provide forward and side imaging. For example, the microscope can be configured to include optical elements needed to dynamically adjust the focal plane to the sample position. This can be performed by, e.g., mechanically moving lens positions, and/or by using a variable optical lens such as a voltage controlled liquid lens technology. In addition or alternatively, such exemplary probe or microscope system can include non-Gaussian imaging beam profiles that feature extended depths of focus. Such exemplary beam profile can be, e.g., a Bessel beam that can be generated for example by using a donut aperture or by an axicon lens.
Because the fiber Bragg grating can be partially transmitting, there can be three separate cavities in the laser. These cavities can be labeled by order in which the circulating light passes through points A 3717a and B 3717b. The longest cavity that provides the desired lasing can pass through both points (cavity ABABA). Two short cavities are also created by the non-zero transmission of the CFBG (cavity AAAAA, cavity BBBBB). Within the CFBG pass band, approximately 30% of the light can be reflected. In addition, wavelengths outside the grating reflection bandwidth are transmitted through the grating with nearly 100% efficiency. Because cavity BBBBB has no optical gain, it is likely not a lasing cavity but can create reflections. Cavity AAAAA can contain the SOA, and can lase which can impact the lasing in cavity ABABA.
Lasing in cavity AAAAA can be suppressed by modulating the SOA and controlling the round trip time of each of the cavities ABABA, AAAAA, and BBBBB. In this exemplary configuration, the round rip time of cavity ABABA can be approximately twice that of cavity AAAAA and cavity BBBBB (see 3702). The exemplary modulation of the SOA 3731 and EOM 3730 can be a suppressed light circulation in these short cavities as shown in graphs 3703. Light/radiation circulating in cavity AAAAA can be blocked by the EOM 3732. Light/radiation circulating in cavity BBBBB can be blocked a all wavelengths of the CFBG by the SOA modulation 3733. Light/radiation circulating in the cavity ABABA can pass through the EOM to the SOA while current is high and then returns to pass through the EOM 3734.
To generate a wavelength-stepped (frequency comb) output, a fixed fused silica FP etalon 3716 with 80 GHz FSR (˜0.64 nm) and low finesse (˜5) can be provided. In one exemplary embodiment, etalons with a FSR between 25 GHz and 400 GHz can be used. When this FP is removed, a continuous wavelength swept operation can be achieved. In the exemplary embodiment of the system 3700, the SOA can be driven with, e.g., a 61 ns current pulse. The round trip of the of the long cavity (ABABA) was 244.75 ns (approximately 50.1 m), e.g., almost 4 times larger than the SOA current pulse. This can produce an approximately 25% duty cycle at the laser output. To increase the A-line rate, a 4× copy-and-paste buffering delay line 3704 can be used to create a 16.3 MHz A-line rate. A booster SOA 3742 was used after the copy-and-paste delay line. The delay line comprised a set of 50/50 couplers (3741a,3741b,3741c) and delay fibers (3743a,3743b). Polarization controllers were included in the paths to align polarization state to the booster SOA 3742.
In this exemplary embodiment, FP etalons with finesse values between 3 and 25 were used to provide low noise operation. In this laser embodiment, a FP etalon with a line width that is broader than the desired lasing line width was used. Lasing provides line width narrowing while the broader FP pass band can yield lower noise performance. For example, the FP can be a solid etalon, or can be constructed from two partial mirrors with an air space between the mirrors. Using air-spaced mirrors can facilitate the FSR of the etalon to be changed dynamically.
It should be understood by those skilled in the art that the output coupler in the laser designs (for example output coupler 3718 shown in
The foregoing merely illustrates the principles of the present disclosure. Various modifications and alterations to the described embodiments will be apparent to those skilled in the art in view of the teachings herein. Indeed, the arrangements, systems and methods according to the exemplary embodiments of the present disclosure can be used with and/or implement any OCT system, OFDI system, SD-OCT system, SECM system, OBM system or other imaging systems capable of imaging in vivo or fresh tissues, and for example with those described in International Patent Application PCT/US2004/029148, filed Sep. 8, 2004 which published as International Patent Publication No. WO 2005/047813 on May 26, 2005, U.S. patent application Ser. No. 11/266,779, filed Nov. 2, 2005 which published as U.S. Patent Publication No. 2006/0093276 on May 4, 2006, and U.S. patent application Ser. No. 10/501,276, filed Jul. 9, 2004 which published as U.S. Patent Publication No. 2005/0018201 on Jan. 27, 2005, U.S. Patent Publication No. 2002/0122246, published on May 9, 2002, U.S. Patent Application No. 61/649,546, U.S. patent application Ser. No. 11/625,135, U.S. Patent Application No. 61/589,083, and International Application No. PCT/US2014/048256, the disclosures of which are incorporated by reference herein in their entireties. It will thus be appreciated that those skilled in the art will be able to devise numerous systems, arrangements and methods which, although not explicitly shown or described herein, embody the principles of the present disclosure and are thus within the spirit and scope of the present disclosure. Further, various exemplary embodiments described herein can be interchangeably used with all other exemplary described embodiments, as should be understood by those having ordinary skill in the art. In addition, to the extent that the prior art knowledge has not been explicitly incorporated by reference herein above, it is explicitly being incorporated herein in its entirety. All publications referenced herein above are incorporated herein by reference in their entireties.
Vakoc, Benjamin, Siddiqui, Meena
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